static void wlanEventHandler(dspT *dsp, ssize_t length, uint8 *rxbuf)
{
bcm_event_t *bcmEvent;
wl_event_msg_t *wlEvent;
int i;
if (length == 0 || rxbuf == 0)
return;
bcmEvent = (bcm_event_t *)rxbuf;
wlEvent = &bcmEvent->event;
wlEvent->flags = ntoh16(wlEvent->flags);
wlEvent->version = ntoh16(wlEvent->version);
wlEvent->event_type = ntoh32(wlEvent->event_type);
wlEvent->status = ntoh32(wlEvent->status);
wlEvent->reason = ntoh32(wlEvent->reason);
wlEvent->auth_type = ntoh32(wlEvent->auth_type);
wlEvent->datalen = ntoh32(wlEvent->datalen);
if (wlEvent->datalen > length - sizeof(bcm_event_t)) {
TRACE(TRACE_ERROR, "invalid data length %d > %d\n",
wlEvent->datalen, length - sizeof(bcm_event_t));
}
for (i = 0; i < MAX_WLAN_HANDLER; i++) {
if (dsp->wlanHandler[i].handler != 0)
(dsp->wlanHandler[i].handler)(
dsp->wlanHandler[i].context,
wlEvent->event_type, wlEvent,
(uint8 *)&bcmEvent[1], wlEvent->datalen);
}
}
static inline int _cpy_fbtrace_meta(char* dst, const uint8_t* body,
um_elist_entry_t* entry) {
int meta_len = ntoh32(entry->data.str.len) - 1;
if (meta_len <= FBTRACE_METADATA_SZ) {
memcpy(dst, body + ntoh32(entry->data.str.offset), meta_len);
} else {
return -1;
}
return 0;
}
void
wl_event_to_host_order(wl_event_msg_t * evt)
{
evt->event_type = ntoh32(evt->event_type);
evt->flags = ntoh16(evt->flags);
evt->status = ntoh32(evt->status);
evt->reason = ntoh32(evt->reason);
evt->auth_type = ntoh32(evt->auth_type);
evt->datalen = ntoh32(evt->datalen);
evt->version = ntoh16(evt->version);
}
void
wl_event_to_host_order(wl_event_msg_t * evt)
{
/* Event struct members passed from dongle to host are stored in network
* byte order. Convert all members to host-order.
*/
evt->event_type = ntoh32(evt->event_type);
evt->flags = ntoh16(evt->flags);
evt->status = ntoh32(evt->status);
evt->reason = ntoh32(evt->reason);
evt->auth_type = ntoh32(evt->auth_type);
evt->datalen = ntoh32(evt->datalen);
evt->version = ntoh16(evt->version);
}
void show_all(struct tcpiphdr *ti) {
uint8_t UNUSED *act;
int UNUSED i;
uint16_t UNUSED *act16;
/*
act = ti;
for(i=0;i<40;i++) {
printf("%d: %d ", i, *act);
act++;
}
act16 = ti;
for(i=0;i<20;i++) {
printf("%d: d%d x%x ", i, *act16, *act16);
act16++;
}
*/
printf("\nipovly\n");
printf("ti_next %d\n", ti->ti_next);
printf("ti_prev %d\n", ti->ti_prev);
printf("ti_x1 %d\n", ti->ti_x1);
printf("ti_pr %d\n", ti->ti_pr);
printf("ti_len %d\n", ti->ti_len);
printf("ti_src %x\n", ti->ti_src.s_addr);
printf("ti_dst %x\n", ti->ti_dst.s_addr);
/*
printf("ti_len %d\n", ntoh16(ti->ti_len));
printf("ti_src %x\n", ntoh32(ti->ti_src.s_addr));
printf("ti_dst %x\n", ntoh32(ti->ti_dst.s_addr));
*/
printf("\ntcp header\n");
/*
printf("ti_sport %d\n", ti->ti_sport);
printf("ti_dport %d\n", ti->ti_dport);
printf("ti_seq %d\n", ti->ti_seq);
printf("ti_ack %d\n", ti->ti_ack);
printf("ti_win %d\n", ti->ti_win);
printf("ti_sum %d\n", ti->ti_sum);
printf("ti_urp %d\n", ti->ti_urp);
*/
printf("ti_sport %d\n", ntoh16(ti->ti_sport));
printf("ti_dport %d\n", ntoh16(ti->ti_dport));
printf("ti_seq %d\n", ntoh32(ti->ti_seq));
printf("ti_ack %d\n", ntoh32(ti->ti_ack));
printf("ti_win %d\n", ntoh16(ti->ti_win));
printf("ti_sum %d\n", ntoh16(ti->ti_sum));
printf("ti_urp %d\n", ntoh16(ti->ti_urp));
}
t_osc_err osc_mem_decodeByteorder(unsigned char typetag, char *data, char **out)
{
size_t size = osc_sizeof(typetag, data);
if(!osc_mem_shouldByteswap(typetag)){
memcpy(*out, data, size);
return OSC_ERR_NONE;
}
char tmp[size];
switch(size){
case 1:
break;
case 2:
*((uint16_t *)tmp) = ntoh16(*((uint16_t *)data));
break;
case 4:
*((uint32_t *)tmp) = ntoh32(*((uint32_t *)data));
break;
case 8:
*((uint64_t *)tmp) = ntoh64(*((uint64_t *)data));
break;
case 16:
*((uint128_t *)tmp) = ntoh128(*((uint128_t *)data));
break;
}
memcpy(*out, tmp, size);
return OSC_ERR_NONE;
}
void print_array_dual (const unsigned char* array, int size)
{
// prints contents of an array
int idx;
int block;
#define NBLOCKS 4
size /= sizeof(u_int32_t);
for (block = 0; block < size; block += NBLOCKS)
{
char ascii4[6];
char ascii[128] = { 0, };
for (idx = block; idx < block + NBLOCKS; idx++)
{
#define H(v) ((unsigned char)(v))
// reads 32 bits word numbered idx and converts it to host endian format if necessary
// (assuming gba/arm's endianness is little-endian like network's convention)
u_int32_t v;
if (idx < size)
v = ntoh32(((u_int32_t*)array)[idx]);
else
v = 0xffffffff;
// print big endian first
print("%02x %02x %02x %02x - ", H(v), H(v>>8), H(v>>16), H(v>>24));
sprintf(ascii4, "%c%c%c%c ", ASCII(v), ASCII(v>>8), ASCII(v>>16), ASCII(v>>24));
strcat(ascii, ascii4);
}
print("%s\n", ascii);
}
}
//获取一个文件列表(每个文件有路径和文件类型两个属性)
vector<file_info> get_server_list(SSL *ssl)
{
vector<file_info> file_list;
uint32_t file_count = 0;
int i = 0;
char file_type;
char *file_path;
ssl_read_wrapper(ssl, &file_count, 4);
file_count = ntoh32(file_count);
for(i = 0; i < (int)file_count; i++)
{
file_path = read_string(ssl);
if(!is_path_safe(std::string(file_path)))
{
fprintf(stderr, "remote host sent illegal path, aborted\n");
exit(1);
}
ssl_read_wrapper(ssl, &file_type, 1);
file_info store(file_path, file_type);
file_list.push_back(store);
free(file_path);
}
return file_list;
}
static void getAllMCMemberRecords(AllocFunction alloc, void *allocUd,
int fd, int agent, UInt16 smLid,
SInt32 *numMRs, struct MCMemberRecord **MRs)
{
UInt8 umad[256];
UInt8 *buf = NULL;
SInt64 len;
SInt32 status;
SInt64 i, n;
SInt32 offset;
struct _MCMemberRecord *p;
const SInt32 timeout = 1000;
fillMAD_Get_MCMemberRecord(umad, sizeof(umad), smLid, 0, __LINE__);
libibumad_Send_MAD(fd, agent, umad, sizeof(umad), timeout, 0);
libibumad_Recv_MAD(alloc, allocUd, fd, &buf, &len, timeout);
status = mad_get_field(umad_get_mad(buf), 0, IB_MAD_STATUS_F);
if (UNLIKELY(0 != status)) {
FATAL("status is %d", status);
}
/* RMPP packets.
*/
offset = mad_get_field(umad_get_mad(buf), 0, IB_SA_ATTROFFS_F);
if (UNLIKELY(0 == offset)) {
FATAL("SA attribute offset is zero.");
}
n = (len - IB_SA_DATA_OFFS)/(offset << 3); /* offset is in 8 byte units */
*numMRs = n;
*MRs = alloc(allocUd, NULL, 0, (*numMRs)*sizeof(struct MCMemberRecord));
for (i = 0 ; i < n; ++i) {
p = (struct _MCMemberRecord *)((UInt8 *)umad_get_mad(buf) + IB_SA_DATA_OFFS + i*(offset << 3));
memcpy((*MRs)[i].mgid, p->mgid, 16);
memcpy((*MRs)[i].portGid, p->portGid, 16);
(*MRs)[i].qkey = ntoh32(p->qkey);
(*MRs)[i].mlid = ntoh16(p->mlid);
(*MRs)[i].mtu = p->mtu;
(*MRs)[i].tclass = p->tclass;
(*MRs)[i].pkey = ntoh16(p->pkey);
(*MRs)[i].rate = p->rate;
(*MRs)[i].packetLife = p->packetLife;
/* FIXME
(*MRs)[i].serviceLevel = p->serviceLevel;
(*MRs)[i].flowLabel = ntoh32(p->flowLabel);
(*MRs)[i].hopLimit = p->hopLimit;
*/
(*MRs)[i].scope = (p->scope_joinState & 0xf0) >> 4;
(*MRs)[i].joinState = p->scope_joinState & 0x0f;
(*MRs)[i].proxyJoin = p->proxyJoin;
}
buf = alloc(allocUd, buf, len, 0);
}
void
i_am_alive_response_received( tNode* pNode, IAnnexET00IAmAlive* pPayload ) {
/* do nothing! remote_host_is_alive() is called from process_pdu() ;-) */
if (sizeof_IAmAliveCookie( pPayload ) >= 4) {
UINT32 send_time = ntoh32( &pPayload[IAnnexET00IAmAlive_COOKIE] );
msaPrintFormat( pNode->pAnnexE->msaType, "IAmAlive response from Host(%08x:%i), delay( %ims )", pNode->RemoteHost.nIP, pNode->RemoteHost.nPort, timerGetTimeInMilliseconds() - send_time );
}
}
int gtpie_gettv4(union gtpie_member* ie[], int type, int instance,
uint32_t *dst){
int ien;
ien = gtpie_getie(ie, type, instance);
if (ien>=0)
*dst = ntoh32(ie[ien]->tv4.v);
else
return EOF;
return 0;
}
static yrmcds_error
parse_dump_record(yrmcds_cnt* c, yrmcds_cnt_response* r) {
if( r->body_length == 0 ) {
// End of dump
return YRMCDS_OK;
}
if( r->body_length < 10 ) {
c->invalid = 1;
return YRMCDS_PROTOCOL_ERROR;
}
r->current_consumption = ntoh32(r->body);
r->max_consumption = ntoh32(r->body + 4);
r->name_length = ntoh16(r->body + 8);
if( r->body_length < 10 + r->name_length ) {
c->invalid = 1;
return YRMCDS_PROTOCOL_ERROR;
}
r->name = r->body + 10;
return YRMCDS_OK;
}
/* send up locally generated event */
void
dhd_sendup_event_common(dhd_pub_t *dhdp, wl_event_msg_t *event, void *data)
{
switch (ntoh32(event->event_type)) {
default:
break;
}
/* Call per-port handler. */
dhd_sendup_event(dhdp, event, data);
}
size_t osc_sizeof(unsigned char typetag, char *data){
if(typetag > 127){
return -1;
}
if(!data){
return -1;
}
switch(typetag){
case 'b':
return ntoh32(*((int32_t *)data)) + 4;
case 's':
case 'S':
return osc_util_getPaddedStringLen(data);
case OSC_BUNDLE_TYPETAG:
return ntoh32(*((uint32_t *)data)) + 4;
case OSC_TIMETAG_TYPETAG:
return OSC_TIMETAG_SIZEOF;
default:
return osc_data_lengths[typetag];
}
}
int32_t osc_message_s_getSize(t_osc_msg_s *m)
{
if(m){
if(m->size){
return ntoh32(*((int32_t *)(m->size)));
}else{
return 0;
}
}else{
return 0;
}
}
void
dhd_sendup_event_common(dhd_pub_t *dhdp, wl_event_msg_t *event, void *data)
{
switch (ntoh32(event->event_type)) {
default:
break;
}
dhd_sendup_event(dhdp, event, data);
}
FSTATUS getFwVersion(struct oib_port *port,
IB_PATH_RECORD *path,
VENDOR_MAD *mad,
uint16 sessionID,
uint8 *fwVersion)
{
FSTATUS status;
uint8 fwVerBuf[FWVERSION_SIZE];
uint32 fwUpper;
uint32 fwLower;
status = sendGetFwVersionMad(port, path, mad, sessionID, fwVerBuf);
if (status == FSUCCESS) {
fwUpper = ntoh32(*(uint32 *)&fwVerBuf[0]);
fwLower = ntoh32(*(uint32 *)&fwVerBuf[4]);
sprintf((char *)fwVersion, "%d.%d.%d.%d.%d",
(fwUpper >> 24) & 0xff,
(fwUpper >> 16) & 0xff,
(fwUpper >> 8) & 0xff,
fwUpper & 0xff,
fwLower);
}
/*** Packet formation *********************************************************/
int pptp_make_packet(PPTP_CONN * conn, void **buf, size_t *size)
{
struct pptp_header *header;
size_t bad_bytes = 0;
assert(conn && conn->call); assert(buf != NULL); assert(size != NULL);
/* Give up unless there are at least sizeof(pptp_header) bytes */
while ((conn->read_size-bad_bytes) >= sizeof(struct pptp_header)) {
/* Throw out bytes until we have a valid header. */
header = (struct pptp_header *) (conn->read_buffer + bad_bytes);
if (ntoh32(header->magic) != PPTP_MAGIC) goto throwitout;
if (ntoh16(header->reserved0) != 0)
log("reserved0 field is not zero! (0x%x) Cisco feature? \n",
ntoh16(header->reserved0));
if (ntoh16(header->length) < sizeof(struct pptp_header)) goto throwitout;
if (ntoh16(header->length) > PPTP_CTRL_SIZE_MAX) goto throwitout;
/* well. I guess it's good. Let's see if we've got it all. */
if (ntoh16(header->length) > (conn->read_size-bad_bytes))
/* nope. Let's wait until we've got it, then. */
goto flushbadbytes;
/* One last check: */
if ((ntoh16(header->pptp_type) == PPTP_MESSAGE_CONTROL) &&
(ntoh16(header->length) !=
PPTP_CTRL_SIZE(ntoh16(header->ctrl_type))))
goto throwitout;
/* well, I guess we've got it. */
*size = ntoh16(header->length);
*buf = malloc(*size);
if (*buf == NULL) { log("Out of memory."); return 0; /* ack! */ }
memcpy(*buf, conn->read_buffer + bad_bytes, *size);
/* Delete this packet from the read_buffer. */
conn->read_size -= (bad_bytes + *size);
memmove(conn->read_buffer, conn->read_buffer + bad_bytes + *size,
conn->read_size);
if (bad_bytes > 0)
log("%lu bad bytes thrown away.", (unsigned long) bad_bytes);
return 1;
throwitout:
bad_bytes++;
}
flushbadbytes:
/* no more packets. Let's get rid of those bad bytes */
conn->read_size -= bad_bytes;
memmove(conn->read_buffer, conn->read_buffer + bad_bytes, conn->read_size);
if (bad_bytes > 0)
log("%lu bad bytes thrown away.", (unsigned long) bad_bytes);
return 0;
}
/* RC - Server only, UD - Server and Client, one per EP */
void process_cr(int idx)
{
DAT_EVENT event;
DAT_COUNT nmore;
DAT_RETURN status;
int pdata;
DAT_CR_HANDLE cr = DAT_HANDLE_NULL;
DAT_CONN_QUAL exp_qual = server ? SERVER_ID : CLIENT_ID;
DAT_CR_PARAM cr_param;
DAT_CR_ARRIVAL_EVENT_DATA *cr_event =
&event.event_data.cr_arrival_event_data;
LOGPRINTF("%s waiting for connect[%d] request\n",
server ? "Server" : "Client", idx);
status = dat_evd_wait(cr_evd, SERVER_TIMEOUT, 1, &event, &nmore);
_OK(status, "CR dat_evd_wait");
if (event.event_number != DAT_CONNECTION_REQUEST_EVENT &&
(ud_test && event.event_number !=
DAT_IB_UD_CONNECTION_REQUEST_EVENT)) {
printf("unexpected event,!conn req: 0x%x\n",
event.event_number);
exit(1);
}
if ((cr_event->conn_qual != exp_qual) ||
(cr_event->sp_handle.psp_handle != psp)) {
printf("wrong cr event data\n");
exit(1);
}
cr = cr_event->cr_handle;
status = dat_cr_query(cr, DAT_CSP_FIELD_ALL, &cr_param);
_OK(status, "dat_cr_query");
/* use private data to select EP */
pdata = ntoh32(*((int *)cr_param.private_data));
LOGPRINTF("%s recvd pdata=0x%x, send pdata=0x%x\n",
server ? "Server" : "Client", pdata,
*(int *)cr_param.private_data);
status = dat_cr_accept(cr, ep[pdata], 4, cr_param.private_data);
_OK(status, "dat_cr_accept");
printf("%s accepted CR on EP[%d]=%p\n",
server ? "Server" : "Client", pdata, ep[pdata]);
}
static void hw_parse_special_dhcp_packet(uint8_t *buff, uint32_t buflen, uint8_t *dst) {
uint8_t type = 0;
uint32_t req_ip = 0;
uint32_t req_srv = 0;
uint32_t len = 0;
struct dhcp_message *msg;
if (buflen <= sizeof(struct dhcp_message)) {
HW_PRINT_HI("%s: invalid dhcp packet\n", __func__);
return;
}
msg = (struct dhcp_message *)buff;
len = buflen - sizeof(struct dhcp_message);
if (hw_dhcp_get_option_uint8(&type, msg->options, len, DHO_MESSAGETYPE) == -1) {
HW_PRINT_HI("%s: get message type failed\n", __func__);
return;
}
if (type == DHCP_DISCOVER) {
HW_PRINT_HI("%s: type: DHCP_DISCOVER\n", __func__);
} else if (type == DHCP_OFFER) {
HW_PRINT_HI("%s: type: DHCP_OFFER, ip:%d.%d.%d.%d srvip:%d.%d.%d.%d MAC:" HWMACSTR "\n",
__func__, IPADDR(msg->yiaddr), IPADDR(msg->siaddr), HWMAC2STR(dst));
} else if (type == DHCP_REQUEST) {
hw_dhcp_get_option_uint32(&req_ip, msg->options, len, DHO_IPADDRESS);
hw_dhcp_get_option_uint32(&req_srv, msg->options, len, DHO_SERVERID);
req_ip = ntoh32(req_ip);
req_srv = ntoh32(req_srv);
HW_PRINT_HI("%s: type: DHCP_REQUEST, ip:%d.%d.%d.%d srvip:%d.%d.%d.%d\n",
__func__, IPADDR(req_ip), IPADDR(req_srv));
} else if (type == DHCP_ACK) {
HW_PRINT_HI("%s: type: DHCP_ACK MAC:" HWMACSTR "\n", __func__, HWMAC2STR(dst));
} else if (type == DHCP_NAK) {
HW_PRINT_HI("%s: type: DHCP_NAK MAC:" HWMACSTR "\n", __func__, HWMAC2STR(dst));
}
}
frm_frame *fetchFRMFrame(unsigned char *buf, uint32_t buflen, uint8_t direct) {
int i = 0;
frm_frame *frame = malloc(sizeof(frm_frame));
if (!frame || buflen < 8)
return NULL;
frame->orient = direct;
frame->width = ntoh16(buf, FRMFRAME_OFFSET_WIDTH);
frame->height = ntoh16(buf, FRMFRAME_OFFSET_HEIGHT);
frame->framesize = ntoh32(buf, FRMFRAME_OFFSET_SIZE);
if (frame->framesize != frame->width * frame->height) {
printf("ERR: Framesize different: %d %d\n", frame->framesize, frame->width * frame->height);
return NULL;
}
if (buflen < (12 + frame->width * frame->height) ) {
return NULL;
}
frame->rowptr = malloc( sizeof(unsigned char *) * frame->height);
if (!frame->rowptr) {
printf("ERROR: no memory\n");
free(frame);
return NULL;
}
for(i=0; i < frame->height; ++i) {
frame->rowptr[i] = malloc(sizeof(unsigned char) * frame->width);
if (!frame->rowptr[i]) {
printf("ERROR: no memory\n");
free(frame);
return NULL;
}
memcpy(frame->rowptr[i], &buf[12]+i*frame->width, frame->width);
}
frame->next_frame = NULL;
return frame;
}
/*** Packet Dispatch **********************************************************/
int pptp_dispatch_packet(PPTP_CONN * conn, void * buffer, size_t size)
{
int r = 0;
struct pptp_header *header = (struct pptp_header *)buffer;
assert(conn && conn->call); assert(buffer);
assert(ntoh32(header->magic) == PPTP_MAGIC);
assert(ntoh16(header->length) == size);
switch (ntoh16(header->pptp_type)) {
case PPTP_MESSAGE_CONTROL:
r = ctrlp_disp(conn, buffer, size);
break;
case PPTP_MESSAGE_MANAGE:
/* MANAGEMENT messages aren't even part of the spec right now. */
log("PPTP management message received, but not understood.");
break;
default:
log("Unknown PPTP control message type received: %u",
(unsigned int) ntoh16(header->pptp_type));
break;
}
return r;
}
t_osc_err osc_message_s_wrap(t_osc_msg_s *m, char *bytes)
{
if(!m || !bytes){
return OSC_ERR_NULLPTR;
}
int32_t len = ntoh32(*((int32_t *)bytes));
m->size = bytes;
char *address = m->address = bytes + 4;
/*
if(!(m->address)){
return OSC_ERR_MALFORMEDADDRESS;
}
if(m->address[0] != '/'){
return OSC_ERR_MALFORMEDADDRESS;
}
*/
/*
m->typetags = bytes + 4 + strlen(bytes + 4) + 1;
while((m->typetags - bytes) % 4){
m->typetags++;
}
*/
char *tt = m->typetags = address + osc_util_getPaddedStringLen(address);
if((tt - bytes) > len){
m->typetags = NULL;
// this isn't really cool--if there is no data, there should at least be a
// comma and 3 NULLs. we'll let it go anyway...
return OSC_ERR_NONE;
}
/*
m->data = m->typetags + strlen(m->typetags) + 1;
while((m->data - bytes) % 4){
m->data++;
}
*/
m->data = tt + osc_util_getPaddedStringLen(tt);
return OSC_ERR_NONE;
}
um_status_t um_parse_header(const uint8_t* buf, size_t nbuf,
um_message_info_t* info_out) {
FBI_ASSERT(info_out);
if (nbuf < sizeof(entry_list_msg_t)) {
return um_not_enough_data;
}
entry_list_msg_t* header = (entry_list_msg_t*) buf;
if (header->msg_header.magic_byte != ENTRY_LIST_MAGIC_BYTE) {
return um_not_umbrella_message;
}
info_out->message_size = ntoh32(header->total_size);
uint16_t nentries = ntoh16(header->nentries);
info_out->header_size = sizeof(entry_list_msg_t) +
sizeof(um_elist_entry_t) * nentries;
if (info_out->header_size > info_out->message_size) {
return um_header_parse_error;
}
info_out->body_size = info_out->message_size - info_out->header_size;
return um_ok;
}
int
wl_host_event(struct dhd_info *dhd, int *ifidx, void *pktdata,
wl_event_msg_t *event, void **data_ptr)
{
/* check whether packet is a BRCM event pkt */
bcm_event_t *pvt_data = (bcm_event_t *)pktdata;
char *event_data;
uint32 type, status;
uint16 flags;
int evlen;
if (bcmp(BRCM_OUI, &pvt_data->bcm_hdr.oui[0], DOT11_OUI_LEN))
return (BCME_ERROR);
/* BRCM event pkt may be unaligned - use xxx_ua to load user_subtype. */
if (ntoh16_ua((void *)&pvt_data->bcm_hdr.usr_subtype) != BCMILCP_BCM_SUBTYPE_EVENT)
return (BCME_ERROR);
*data_ptr = &pvt_data[1];
event_data = *data_ptr;
/* memcpy since BRCM event pkt may be unaligned. */
memcpy(event, &pvt_data->event, sizeof(wl_event_msg_t));
type = ntoh32_ua((void *)&event->event_type);
flags = ntoh16_ua((void *)&event->flags);
status = ntoh32_ua((void *)&event->status);
evlen = ntoh32_ua((void *)&event->datalen) + sizeof(bcm_event_t);
switch (type) {
case WLC_E_IF:
{
dhd_if_event_t *ifevent = (dhd_if_event_t *)event_data;
if (ifevent->ifidx > 0 && ifevent->ifidx < DHD_MAX_IFS)
{
if (ifevent->action == WLC_E_IF_ADD)
dhd_add_if(dhd, ifevent->ifidx,
NULL, event->ifname,
pvt_data->eth.ether_dhost,
ifevent->flags, ifevent->bssidx);
else
dhd_del_if(dhd, ifevent->ifidx);
} else {
DHD_ERROR(("%s: Invalid ifidx %d for %s\n",
__FUNCTION__, ifevent->ifidx, event->ifname));
}
}
/* send up the if event: btamp user needs it */
*ifidx = dhd_ifname2idx(dhd, event->ifname);
/* push up to external supp/auth */
dhd_event(dhd, (char *)pvt_data, evlen, *ifidx);
break;
/* fall through */
/* These are what external supplicant/authenticator wants */
case WLC_E_LINK:
case WLC_E_ASSOC_IND:
case WLC_E_REASSOC_IND:
case WLC_E_DISASSOC_IND:
case WLC_E_MIC_ERROR:
default:
/* Fall through: this should get _everything_ */
*ifidx = dhd_ifname2idx(dhd, event->ifname);
/* push up to external supp/auth */
dhd_event(dhd, (char *)pvt_data, evlen, *ifidx);
DHD_TRACE(("%s: MAC event %d, flags %x, status %x\n",
__FUNCTION__, type, flags, status));
/* put it back to WLC_E_NDIS_LINK */
if (type == WLC_E_NDIS_LINK) {
uint32 temp;
temp = ntoh32_ua((void *)&event->event_type);
DHD_TRACE(("Converted to WLC_E_LINK type %d\n", temp));
temp = ntoh32(WLC_E_NDIS_LINK);
memcpy((void *)(&pvt_data->event.event_type), &temp,
sizeof(pvt_data->event.event_type));
}
break;
}
#ifdef SHOW_EVENTS
wl_show_host_event(event, event_data);
#endif /* SHOW_EVENTS */
return (BCME_OK);
}
static void
wl_show_host_event(wl_event_msg_t *event, void *event_data)
{
uint i, status, reason;
bool group = FALSE, flush_txq = FALSE, link = FALSE;
char *auth_str, *event_name;
uchar *buf;
char err_msg[256], eabuf[ETHER_ADDR_STR_LEN];
static struct {uint event; char *event_name;} event_names[] = {
{WLC_E_SET_SSID, "SET_SSID"},
{WLC_E_JOIN, "JOIN"},
{WLC_E_START, "START"},
{WLC_E_AUTH, "AUTH"},
{WLC_E_AUTH_IND, "AUTH_IND"},
{WLC_E_DEAUTH, "DEAUTH"},
{WLC_E_DEAUTH_IND, "DEAUTH_IND"},
{WLC_E_ASSOC, "ASSOC"},
{WLC_E_ASSOC_IND, "ASSOC_IND"},
{WLC_E_REASSOC, "REASSOC"},
{WLC_E_REASSOC_IND, "REASSOC_IND"},
{WLC_E_DISASSOC, "DISASSOC"},
{WLC_E_DISASSOC_IND, "DISASSOC_IND"},
{WLC_E_QUIET_START, "START_QUIET"},
{WLC_E_QUIET_END, "END_QUIET"},
{WLC_E_BEACON_RX, "BEACON_RX"},
{WLC_E_LINK, "LINK"},
{WLC_E_MIC_ERROR, "MIC_ERROR"},
{WLC_E_NDIS_LINK, "NDIS_LINK"},
{WLC_E_ROAM, "ROAM"},
{WLC_E_TXFAIL, "TXFAIL"},
{WLC_E_PMKID_CACHE, "PMKID_CACHE"},
{WLC_E_RETROGRADE_TSF, "RETROGRADE_TSF"},
{WLC_E_PRUNE, "PRUNE"},
{WLC_E_AUTOAUTH, "AUTOAUTH"},
{WLC_E_EAPOL_MSG, "EAPOL_MSG"},
{WLC_E_SCAN_COMPLETE, "SCAN_COMPLETE"},
{WLC_E_ADDTS_IND, "ADDTS_IND"},
{WLC_E_DELTS_IND, "DELTS_IND"},
{WLC_E_BCNSENT_IND, "BCNSENT_IND"},
{WLC_E_BCNRX_MSG, "BCNRX_MSG"},
{WLC_E_BCNLOST_MSG, "BCNLOST_MSG"},
{WLC_E_ROAM_PREP, "ROAM_PREP"},
{WLC_E_PFN_NET_FOUND, "PNO_NET_FOUND"},
{WLC_E_PFN_NET_LOST, "PNO_NET_LOST"},
{WLC_E_RESET_COMPLETE, "RESET_COMPLETE"},
{WLC_E_JOIN_START, "JOIN_START"},
{WLC_E_ROAM_START, "ROAM_START"},
{WLC_E_ASSOC_START, "ASSOC_START"},
{WLC_E_IBSS_ASSOC, "IBSS_ASSOC"},
{WLC_E_RADIO, "RADIO"},
{WLC_E_PSM_WATCHDOG, "PSM_WATCHDOG"},
{WLC_E_PROBREQ_MSG, "PROBREQ_MSG"},
{WLC_E_SCAN_CONFIRM_IND, "SCAN_CONFIRM_IND"},
{WLC_E_PSK_SUP, "PSK_SUP"},
{WLC_E_COUNTRY_CODE_CHANGED, "COUNTRY_CODE_CHANGED"},
{WLC_E_EXCEEDED_MEDIUM_TIME, "EXCEEDED_MEDIUM_TIME"},
{WLC_E_ICV_ERROR, "ICV_ERROR"},
{WLC_E_UNICAST_DECODE_ERROR, "UNICAST_DECODE_ERROR"},
{WLC_E_MULTICAST_DECODE_ERROR, "MULTICAST_DECODE_ERROR"},
{WLC_E_TRACE, "TRACE"},
{WLC_E_ACTION_FRAME, "ACTION FRAME"},
{WLC_E_ACTION_FRAME_COMPLETE, "ACTION FRAME TX COMPLETE"},
{WLC_E_IF, "IF"},
{WLC_E_RSSI, "RSSI"},
{WLC_E_PFN_SCAN_COMPLETE, "SCAN_COMPLETE"}
};
uint event_type, flags, auth_type, datalen;
event_type = ntoh32(event->event_type);
flags = ntoh16(event->flags);
status = ntoh32(event->status);
reason = ntoh32(event->reason);
auth_type = ntoh32(event->auth_type);
datalen = ntoh32(event->datalen);
/* debug dump of event messages */
sprintf(eabuf, "%02x:%02x:%02x:%02x:%02x:%02x",
(uchar)event->addr.octet[0]&0xff,
(uchar)event->addr.octet[1]&0xff,
(uchar)event->addr.octet[2]&0xff,
(uchar)event->addr.octet[3]&0xff,
(uchar)event->addr.octet[4]&0xff,
(uchar)event->addr.octet[5]&0xff);
event_name = "UNKNOWN";
for (i = 0; i < ARRAYSIZE(event_names); i++) {
if (event_names[i].event == event_type)
event_name = event_names[i].event_name;
}
if (flags & WLC_EVENT_MSG_LINK)
link = TRUE;
if (flags & WLC_EVENT_MSG_GROUP)
group = TRUE;
if (flags & WLC_EVENT_MSG_FLUSHTXQ)
flush_txq = TRUE;
switch (event_type) {
case WLC_E_START:
case WLC_E_DEAUTH:
case WLC_E_DISASSOC:
DHD_EVENT(("MACEVENT: %s, MAC %s\n", event_name, eabuf));
break;
case WLC_E_ASSOC_IND:
case WLC_E_REASSOC_IND:
#ifdef APSTA_PINGTEST
{
int i;
for (i = 0; i < MAX_GUEST; ++i)
if (ETHER_ISNULLADDR(&guest_eas[i]))
break;
if (i < MAX_GUEST)
bcopy(event->addr.octet, guest_eas[i].octet, ETHER_ADDR_LEN);
}
#endif /* APSTA_PINGTEST */
DHD_EVENT(("MACEVENT: %s, MAC %s\n", event_name, eabuf));
break;
case WLC_E_ASSOC:
case WLC_E_REASSOC:
if (status == WLC_E_STATUS_SUCCESS) {
DHD_EVENT(("MACEVENT: %s, MAC %s, SUCCESS\n", event_name, eabuf));
} else if (status == WLC_E_STATUS_TIMEOUT) {
DHD_EVENT(("MACEVENT: %s, MAC %s, TIMEOUT\n", event_name, eabuf));
} else if (status == WLC_E_STATUS_FAIL) {
DHD_EVENT(("MACEVENT: %s, MAC %s, FAILURE, reason %d\n",
event_name, eabuf, (int)reason));
} else {
DHD_EVENT(("MACEVENT: %s, MAC %s, unexpected status %d\n",
event_name, eabuf, (int)status));
}
break;
case WLC_E_DEAUTH_IND:
case WLC_E_DISASSOC_IND:
#ifdef APSTA_PINGTEST
{
int i;
for (i = 0; i < MAX_GUEST; ++i) {
if (bcmp(guest_eas[i].octet, event->addr.octet,
ETHER_ADDR_LEN) == 0) {
bzero(guest_eas[i].octet, ETHER_ADDR_LEN);
break;
}
}
}
#endif /* APSTA_PINGTEST */
DHD_EVENT(("MACEVENT: %s, MAC %s, reason %d\n", event_name, eabuf, (int)reason));
break;
case WLC_E_AUTH:
case WLC_E_AUTH_IND:
if (auth_type == DOT11_OPEN_SYSTEM)
auth_str = "Open System";
else if (auth_type == DOT11_SHARED_KEY)
auth_str = "Shared Key";
else {
sprintf(err_msg, "AUTH unknown: %d", (int)auth_type);
auth_str = err_msg;
}
if (event_type == WLC_E_AUTH_IND) {
DHD_EVENT(("MACEVENT: %s, MAC %s, %s\n", event_name, eabuf, auth_str));
} else if (status == WLC_E_STATUS_SUCCESS) {
DHD_EVENT(("MACEVENT: %s, MAC %s, %s, SUCCESS\n",
event_name, eabuf, auth_str));
} else if (status == WLC_E_STATUS_TIMEOUT) {
DHD_EVENT(("MACEVENT: %s, MAC %s, %s, TIMEOUT\n",
event_name, eabuf, auth_str));
} else if (status == WLC_E_STATUS_FAIL) {
DHD_EVENT(("MACEVENT: %s, MAC %s, %s, FAILURE, reason %d\n",
event_name, eabuf, auth_str, (int)reason));
}
break;
case WLC_E_JOIN:
case WLC_E_ROAM:
case WLC_E_SET_SSID:
if (status == WLC_E_STATUS_SUCCESS) {
DHD_EVENT(("MACEVENT: %s, MAC %s\n", event_name, eabuf));
} else if (status == WLC_E_STATUS_FAIL) {
DHD_EVENT(("MACEVENT: %s, failed\n", event_name));
} else if (status == WLC_E_STATUS_NO_NETWORKS) {
DHD_EVENT(("MACEVENT: %s, no networks found\n", event_name));
} else {
DHD_EVENT(("MACEVENT: %s, unexpected status %d\n",
event_name, (int)status));
}
break;
case WLC_E_BEACON_RX:
if (status == WLC_E_STATUS_SUCCESS) {
DHD_EVENT(("MACEVENT: %s, SUCCESS\n", event_name));
} else if (status == WLC_E_STATUS_FAIL) {
DHD_EVENT(("MACEVENT: %s, FAIL\n", event_name));
} else {
DHD_EVENT(("MACEVENT: %s, status %d\n", event_name, status));
}
break;
case WLC_E_LINK:
DHD_EVENT(("MACEVENT: %s %s\n", event_name, link?"UP":"DOWN"));
break;
case WLC_E_MIC_ERROR:
DHD_EVENT(("MACEVENT: %s, MAC %s, Group %d, Flush %d\n",
event_name, eabuf, group, flush_txq));
break;
case WLC_E_ICV_ERROR:
case WLC_E_UNICAST_DECODE_ERROR:
case WLC_E_MULTICAST_DECODE_ERROR:
DHD_EVENT(("MACEVENT: %s, MAC %s\n",
event_name, eabuf));
break;
case WLC_E_TXFAIL:
DHD_EVENT(("MACEVENT: %s, RA %s\n", event_name, eabuf));
break;
case WLC_E_SCAN_COMPLETE:
case WLC_E_PMKID_CACHE:
DHD_EVENT(("MACEVENT: %s\n", event_name));
break;
case WLC_E_PFN_NET_FOUND:
case WLC_E_PFN_NET_LOST:
case WLC_E_PFN_SCAN_COMPLETE:
DHD_EVENT(("PNOEVENT: %s\n", event_name));
break;
case WLC_E_PSK_SUP:
case WLC_E_PRUNE:
DHD_EVENT(("MACEVENT: %s, status %d, reason %d\n",
event_name, (int)status, (int)reason));
break;
case WLC_E_TRACE:
{
static uint32 seqnum_prev = 0;
msgtrace_hdr_t hdr;
uint32 nblost;
char *s, *p;
buf = (uchar *) event_data;
memcpy(&hdr, buf, MSGTRACE_HDRLEN);
if (hdr.version != MSGTRACE_VERSION) {
printf("\nMACEVENT: %s [unsupported version --> "
"dhd version:%d dongle version:%d]\n",
event_name, MSGTRACE_VERSION, hdr.version);
/* Reset datalen to avoid display below */
datalen = 0;
break;
}
/* There are 2 bytes available at the end of data */
buf[MSGTRACE_HDRLEN + ntoh16(hdr.len)] = '\0';
if (ntoh32(hdr.discarded_bytes) || ntoh32(hdr.discarded_printf)) {
printf("\nWLC_E_TRACE: [Discarded traces in dongle -->"
"discarded_bytes %d discarded_printf %d]\n",
ntoh32(hdr.discarded_bytes), ntoh32(hdr.discarded_printf));
}
nblost = ntoh32(hdr.seqnum) - seqnum_prev - 1;
if (nblost > 0) {
printf("\nWLC_E_TRACE: [Event lost --> seqnum %d nblost %d\n",
ntoh32(hdr.seqnum), nblost);
}
seqnum_prev = ntoh32(hdr.seqnum);
/* Display the trace buffer. Advance from \n to \n to avoid display big
* printf (issue with Linux printk )
*/
p = &(buf[MSGTRACE_HDRLEN]);
while ((s = strstr(p, "\n")) != NULL) {
*s = '\0';
printf("%s\n", p);
p = s+1;
}
printf("%s\n", p);
/* Reset datalen to avoid display below */
datalen = 0;
}
break;
case WLC_E_RSSI:
DHD_EVENT(("MACEVENT: %s %d\n", event_name, ntoh32(*((int *)event_data))));
break;
default:
DHD_EVENT(("MACEVENT: %s %d, MAC %s, status %d, reason %d, auth %d\n",
event_name, event_type, eabuf, (int)status, (int)reason,
(int)auth_type));
break;
}
/* show any appended data */
if (datalen) {
buf = (uchar *) event_data;
DHD_EVENT((" data (%d) : ", datalen));
for (i = 0; i < datalen; i++)
DHD_EVENT((" 0x%02x ", *buf++));
DHD_EVENT(("\n"));
}
}
s32
wl_cfgnan_notify_nan_status(struct bcm_cfg80211 *cfg,
bcm_struct_cfgdev *cfgdev, const wl_event_msg_t *event, void *data)
{
s32 ret = BCME_OK;
u16 data_len;
u32 event_num;
s32 event_type;
nan_event_hdr_t nan_hdr;
wl_nan_tlv_data_t tlv_data;
u8 *buf = NULL;
u32 buf_len;
u8 *ptr;
u16 kflags = in_atomic() ? GFP_ATOMIC : GFP_KERNEL;
if (!event || !data) {
WL_ERR((" event data is NULL \n"));
return -EINVAL;
}
event_type = ntoh32(event->event_type);
event_num = ntoh32(event->reason);
data_len = ntoh32(event->datalen);
memset(&nan_hdr, 0, sizeof(nan_event_hdr_t));
nan_hdr.event_subtype = event_num;
WL_DBG((" nan event: type: %d num: %d len: %d \n",
event_type, event_num, data_len));
if (INVALID_NAN_EVENT(event_num)) {
WL_ERR((" unsupported event, num: %d \n", event_num));
return -EINVAL;
}
if (g_nan_debug) {
WL_DBG((" event name: %s \n", nan_event_name[event_num]));
WL_DBG((" event data: \n"));
prhex(NULL, data, data_len);
}
/* unpack the tlvs */
memset(&tlv_data, 0, sizeof(wl_nan_tlv_data_t));
bcm_unpack_xtlv_buf(&tlv_data, data, data_len,
wl_cfgnan_set_vars_cbfn);
/*
* send as preformatted hex string
*
* EVENT_NAN <event_type> <tlv_hex_string>
*/
buf_len = NAN_IOCTL_BUF_SIZE;
buf = ptr = kzalloc(buf_len, kflags);
if (!buf) {
WL_ERR((" memory allocation failed \n"));
ret = -ENOMEM;
goto fail;
}
switch (event_num) {
case WL_NAN_EVENT_START:
case WL_NAN_EVENT_JOIN:
case WL_NAN_EVENT_STOP:
ptr += sprintf(buf, SUPP_EVENT_PREFIX"%s " CLUS_ID_PREFIX MACF,
nan_event_str[event_num], ETHER_TO_MACF(tlv_data.nstatus.cid));
break;
case WL_NAN_EVENT_ROLE:
ptr += sprintf(buf, SUPP_EVENT_PREFIX"%s "ROLE_PREFIX "%d "
CLUS_ID_PREFIX MACF, nan_event_str[event_num],
tlv_data.nstatus.role, ETHER_TO_MACF(tlv_data.nstatus.cid));
break;
case WL_NAN_EVENT_DISCOVERY_RESULT:
ptr += sprintf(buf, SUPP_EVENT_PREFIX"%s " PUB_ID_PREFIX"%d "
SUB_ID_PREFIX"%d " MAC_ADDR_PREFIX MACF,
nan_event_str[event_num], tlv_data.pub_id, tlv_data.sub_id,
ETHER_TO_MACF(tlv_data.mac_addr));
if (tlv_data.svc_info.data && tlv_data.svc_info.dlen) {
WL_DBG((" service info present \n"));
if ((strlen(ptr) + tlv_data.svc_info.dlen) >= buf_len) {
WL_ERR((" service info length = %d\n",
tlv_data.svc_info.dlen));
WL_ERR((" insufficent buffer to copy service info \n"));
ret = -EOVERFLOW;
goto fail;
}
ptr += sprintf(ptr, " %s", SVC_INFO_PREFIX);
ptr += bcm_format_hex(ptr, tlv_data.svc_info.data,
tlv_data.svc_info.dlen);
} else {
WL_DBG((" service info not present \n"));
}
if (tlv_data.vend_info.data && tlv_data.vend_info.dlen) {
struct ether_addr *ea;
u8 *data = tlv_data.vend_info.data;
uint32 bitmap;
u16 dlen = tlv_data.vend_info.dlen;
chanspec_t chanspec;
uint8 mapcontrol;
uint8 proto;
WL_DBG((" vendor info present \n"));
if ((*data != NAN_ATTR_VENDOR_SPECIFIC) ||
(dlen < NAN_VENDOR_HDR_SIZE)) {
WL_ERR((" error in vendor info attribute \n"));
ret = -EINVAL;
goto fail;
} else {
WL_DBG((" vendor info not present \n"));
}
if (*(data + 6) == NAN_VENDOR_TYPE_RTT) {
data += NAN_VENDOR_HDR_SIZE;
ea = (struct ether_addr *)data;
data += ETHER_ADDR_LEN;
mapcontrol = *data++;
proto = *data++;
bitmap = *(uint32 *)data;
data += 4;
chanspec = *(chanspec_t *)data;
ptr += sprintf(ptr, " "BITMAP_PREFIX"0x%x "CHAN_PREFIX"%d/%s",
bitmap, wf_chspec_ctlchan(chanspec),
wf_chspec_to_bw_str(chanspec));
WL_DBG((" bitmap: 0x%x channel: %d bandwidth: %s \n", bitmap,
wf_chspec_ctlchan(chanspec),
wf_chspec_to_bw_str(chanspec)));
}
}
break;
case WL_NAN_EVENT_REPLIED:
ptr += sprintf(buf, SUPP_EVENT_PREFIX"%s " PUB_ID_PREFIX"%d "
MAC_ADDR_PREFIX MACF, nan_event_str[event_num],
tlv_data.pub_id, ETHER_TO_MACF(tlv_data.mac_addr));
break;
case WL_NAN_EVENT_TERMINATED:
ptr += sprintf(buf, SUPP_EVENT_PREFIX"%s " PUB_ID_PREFIX"%d ",
nan_event_str[event_num], tlv_data.pub_id);
break;
case WL_NAN_EVENT_RECEIVE:
ptr += sprintf(buf, SUPP_EVENT_PREFIX"%s " PUB_ID_PREFIX"%d "
MAC_ADDR_PREFIX MACF, nan_event_str[event_num],
tlv_data.pub_id, ETHER_TO_MACF(tlv_data.mac_addr));
if (tlv_data.svc_info.data && tlv_data.svc_info.dlen) {
WL_DBG((" service info present \n"));
if ((strlen(ptr) + tlv_data.svc_info.dlen) >= buf_len) {
WL_ERR((" service info length = %d\n",
tlv_data.svc_info.dlen));
WL_ERR((" insufficent buffer to copy service info \n"));
ret = -EOVERFLOW;
goto fail;
}
ptr += sprintf(ptr, " %s", SVC_INFO_PREFIX);
ptr += bcm_format_hex(ptr, tlv_data.svc_info.data,
tlv_data.svc_info.dlen);
} else {
WL_DBG((" service info not present \n"));
}
break;
case WL_NAN_EVENT_SCAN_COMPLETE:
ptr += sprintf(buf, SUPP_EVENT_PREFIX"%s " CLUS_ID_PREFIX MACF,
nan_event_str[event_num], ETHER_TO_MACF(tlv_data.nstatus.cid));
break;
case WL_NAN_EVENT_STATUS_CHG:
ptr += sprintf(buf, SUPP_EVENT_PREFIX"%s " CLUS_ID_PREFIX MACF,
nan_event_str[event_num], ETHER_TO_MACF(tlv_data.nstatus.cid));
break;
case WL_NAN_EVENT_MERGE:
ptr += sprintf(buf, SUPP_EVENT_PREFIX"%s " CLUS_ID_PREFIX MACF,
nan_event_str[event_num], ETHER_TO_MACF(tlv_data.nstatus.cid));
break;
default:
WL_ERR((" unknown event \n"));
break;
}
#ifdef WL_GENL
/* send the preformatted string to the upper layer as event */
WL_DBG((" formatted string for userspace: %s, len: %zu \n",
buf, strlen(buf)));
wl_genl_send_msg(bcmcfg_to_prmry_ndev(cfg), 0, buf, strlen(buf), 0, 0);
#endif /* WL_GENL */
fail:
if (buf) {
kfree(buf);
}
if (tlv_data.svc_info.data) {
kfree(tlv_data.svc_info.data);
tlv_data.svc_info.data = NULL;
tlv_data.svc_info.dlen = 0;
}
if (tlv_data.vend_info.data) {
kfree(tlv_data.vend_info.data);
tlv_data.vend_info.data = NULL;
tlv_data.vend_info.dlen = 0;
}
return ret;
}
s32
wl_cfgnan_notify_proxd_status(struct bcm_cfg80211 *cfg,
bcm_struct_cfgdev *cfgdev, const wl_event_msg_t *event, void *data)
{
s32 ret = BCME_OK;
wl_nan_ranging_event_data_t *rdata;
s32 status;
u16 data_len;
s32 event_type;
s32 event_num;
u8 *buf = NULL;
u32 buf_len;
u8 *ptr;
u16 kflags = in_atomic() ? GFP_ATOMIC : GFP_KERNEL;
s32 i;
if (!event || !data) {
WL_ERR((" event data is NULL \n"));
return -EINVAL;
}
status = ntoh32(event->reason);
event_type = ntoh32(event->event_type);
event_num = ntoh32(event->reason);
data_len = ntoh32(event->datalen);
WL_DBG((" proxd event: type: %d num: %d len: %d \n",
event_type, event_num, data_len));
if (INVALID_PROXD_EVENT(event_num)) {
WL_ERR((" unsupported event, num: %d \n", event_num));
return -EINVAL;
}
if (g_nan_debug) {
WL_DBG((" event name: WLC_E_PROXD_NAN_EVENT \n"));
WL_DBG((" event data: \n"));
prhex(NULL, data, data_len);
}
if (data_len < sizeof(wl_nan_ranging_event_data_t)) {
WL_ERR((" wrong data len \n"));
return -EINVAL;
}
rdata = (wl_nan_ranging_event_data_t *)data;
WL_DBG((" proxd event: count:%d success_count:%d mode:%d \n",
rdata->count, rdata->success_count, rdata->mode));
if (g_nan_debug) {
prhex(" event data: ", data, data_len);
}
buf_len = NAN_IOCTL_BUF_SIZE;
buf = kzalloc(buf_len, kflags);
if (!buf) {
WL_ERR((" memory allocation failed \n"));
return -ENOMEM;
}
for (i = 0; i < rdata->count; i++) {
if (&rdata->rr[i] == NULL) {
ret = -EINVAL;
goto fail;
}
ptr = buf;
WL_DBG((" ranging data for mac:"MACDBG" \n",
MAC2STRDBG(rdata->rr[i].ea.octet)));
ptr += sprintf(buf, SUPP_EVENT_PREFIX"%s " MAC_ADDR_PREFIX MACF
" "STATUS_PREFIX"%s", EVENT_RTT_STATUS_STR,
ETHER_TO_MACF(rdata->rr[i].ea), (rdata->rr[i].status == 1) ?
"success" : "fail");
if (rdata->rr[i].status == 1) {
/* add tsf and distance only if status is success */
ptr += sprintf(ptr, " "TIMESTAMP_PREFIX"0x%x "
DISTANCE_PREFIX"%d.%04d", rdata->rr[i].timestamp,
rdata->rr[i].distance >> 4,
((rdata->rr[i].distance & 0x0f) * 625));
}
#ifdef WL_GENL
/* send the preformatted string to the upper layer as event */
WL_DBG((" formatted string for userspace: %s, len: %zu \n",
buf, strlen(buf)));
wl_genl_send_msg(bcmcfg_to_prmry_ndev(cfg), 0, buf, strlen(buf), 0, 0);
#endif /* WL_GENL */
}
yrmcds_error
yrmcds_cnt_recv(yrmcds_cnt* c, yrmcds_cnt_response* r) {
if( c == NULL || r == NULL )
return YRMCDS_BAD_ARGUMENT;
if( c->invalid )
return YRMCDS_PROTOCOL_ERROR;
if( c->last_size > 0 ) {
size_t remain = c->used - c->last_size;
if( remain > 0 )
memmove(c->recvbuf, c->recvbuf + c->last_size, remain);
c->used = remain;
c->last_size = 0;
}
while( c->used < HEADER_SIZE ) {
yrmcds_error e = recv_data(c);
if( e != YRMCDS_OK ) return e;
}
if( (uint8_t)c->recvbuf[0] != 0x91 ) {
c->invalid = 1;
return YRMCDS_PROTOCOL_ERROR;
}
r->command = (yrmcds_cnt_command)c->recvbuf[1];
r->status = (yrmcds_cnt_status)c->recvbuf[2];
r->body_length = ntoh32(c->recvbuf + 4);
memcpy(&r->serial, c->recvbuf + 8, sizeof(r->serial));
r->body = NULL;
r->resources = 0;
r->current_consumption = 0;
r->max_consumption = 0;
r->name_length = 0;
r->stats = NULL;
if( r->body_length > 0 ) {
while( c->used < HEADER_SIZE + r->body_length ) {
yrmcds_error e = recv_data(c);
if( e != YRMCDS_OK ) return e;
}
r->body = c->recvbuf + HEADER_SIZE;
}
c->last_size = HEADER_SIZE + r->body_length;
if( r->status != YRMCDS_STATUS_OK )
return YRMCDS_OK;
yrmcds_error err;
switch( r->command ) {
case YRMCDS_CNT_CMD_GET:
if( r->body_length < 4 ) {
c->invalid = 1;
return YRMCDS_PROTOCOL_ERROR;
}
r->current_consumption = ntoh32(r->body);
break;
case YRMCDS_CNT_CMD_ACQUIRE:
if( r->body_length < 4 ) {
c->invalid = 1;
return YRMCDS_PROTOCOL_ERROR;
}
r->resources = ntoh32(r->body);
break;
case YRMCDS_CNT_CMD_STATS:
err = parse_statistics(c, r);
if( err != YRMCDS_OK ) {
c->invalid = 1;
return err;
}
r->stats = &c->stats;
break;
case YRMCDS_CNT_CMD_DUMP:
err = parse_dump_record(c, r);
if( err != YRMCDS_OK ) {
c->invalid = 1;
return err;
}
break;
default:
// No body
break;
}
return YRMCDS_OK;
}
/*** decaps_gre ***************************************************************/
int decaps_gre (int fd, callback_t callback, int cl)
{
unsigned char buffer[PACKET_MAX + 64 /*ip header*/];
struct pptp_gre_header *header;
int status, ip_len = 0;
static int first = 1;
unsigned int headersize;
unsigned int payload_len;
u_int32_t seq;
if ((status = read (fd, buffer, sizeof(buffer))) <= 0) {
warn("short read (%d): %s", status, strerror(errno));
stats.rx_errors++;
return -1;
}
/* strip off IP header, if present */
if ((buffer[0] & 0xF0) == 0x40)
ip_len = (buffer[0] & 0xF) * 4;
header = (struct pptp_gre_header *)(buffer + ip_len);
/* verify packet (else discard) */
if ( /* version should be 1 */
((ntoh8(header->ver) & 0x7F) != PPTP_GRE_VER) ||
/* PPTP-GRE protocol for PPTP */
(ntoh16(header->protocol) != PPTP_GRE_PROTO)||
/* flag C should be clear */
PPTP_GRE_IS_C(ntoh8(header->flags)) ||
/* flag R should be clear */
PPTP_GRE_IS_R(ntoh8(header->flags)) ||
/* flag K should be set */
(!PPTP_GRE_IS_K(ntoh8(header->flags))) ||
/* routing and recursion ctrl = 0 */
((ntoh8(header->flags)&0xF) != 0)) {
/* if invalid, discard this packet */
warn("Discarding GRE: %X %X %X %X %X %X",
ntoh8(header->ver)&0x7F, ntoh16(header->protocol),
PPTP_GRE_IS_C(ntoh8(header->flags)),
PPTP_GRE_IS_R(ntoh8(header->flags)),
PPTP_GRE_IS_K(ntoh8(header->flags)),
ntoh8(header->flags) & 0xF);
stats.rx_invalid++;
return 0;
}
/* silently discard packets not for this call */
if (ntoh16(header->call_id) != pptp_gre_call_id) return 0;
/* test if acknowledgement present */
if (PPTP_GRE_IS_A(ntoh8(header->ver))) {
u_int32_t ack = (PPTP_GRE_IS_S(ntoh8(header->flags)))?
header->ack:header->seq; /* ack in different place if S = 0 */
ack = ntoh32( ack);
if (ack > ack_recv) ack_recv = ack;
/* also handle sequence number wrap-around */
if (WRAPPED(ack,ack_recv)) ack_recv = ack;
if (ack_recv == stats.pt.seq) {
int rtt = time_now_usecs() - stats.pt.time;
stats.rtt = (stats.rtt + rtt) / 2;
}
}
/* test if payload present */
if (!PPTP_GRE_IS_S(ntoh8(header->flags)))
return 0; /* ack, but no payload */
headersize = sizeof(*header);
payload_len = ntoh16(header->payload_len);
seq = ntoh32(header->seq);
/* no ack present? */
if (!PPTP_GRE_IS_A(ntoh8(header->ver))) headersize -= sizeof(header->ack);
/* check for incomplete packet (length smaller than expected) */
if (status - headersize < payload_len) {
warn("discarding truncated packet (expected %d, got %d bytes)",
payload_len, status - headersize);
stats.rx_truncated++;
return 0;
}
/* check for expected sequence number */
if ( first || (seq == seq_recv + 1)) { /* wrap-around safe */
if ( log_level >= 2 )
log("accepting packet %d", seq);
stats.rx_accepted++;
first = 0;
seq_recv = seq;
return callback(cl, buffer + ip_len + headersize, payload_len);
/* out of order, check if the number is too low and discard the packet.
* (handle sequence number wrap-around, and try to do it right) */
} else if ( seq < seq_recv + 1 || WRAPPED(seq_recv, seq) ) {
if ( log_level >= 1 )
log("discarding duplicate or old packet %d (expecting %d)",
seq, seq_recv + 1);
stats.rx_underwin++;
/* sequence number too high, is it reasonably close? */
} else if ( seq < seq_recv + MISSING_WINDOW ||
WRAPPED(seq, seq_recv + MISSING_WINDOW) ) {
stats.rx_buffered++;
if ( log_level >= 1 )
log("%s packet %d (expecting %d, lost or reordered)",
disable_buffer ? "accepting" : "buffering",
seq, seq_recv+1);
if ( disable_buffer ) {
seq_recv = seq;
stats.rx_lost += seq - seq_recv - 1;
return callback(cl, buffer + ip_len + headersize, payload_len);
} else {
pqueue_add(seq, buffer + ip_len + headersize, payload_len);
}
/* no, packet must be discarded */
} else {
if ( log_level >= 1 )
warn("discarding bogus packet %d (expecting %d)",
seq, seq_recv + 1);
stats.rx_overwin++;
}
return 0;
}
